Despite advances in genomics in recent years, schizophrenia remains one of the most complex challenges of both genetics and neuroscience. The chromosomal abnormality 22q11 deletion syndrome, also known as DiGeorge syndrome, offers a way in, since it is one of the strongest genetic risk factors for schizophrenia.
Out of dozens of genes within the 22q11 deletion, several encode proteins found in mitochondria. A team of Emory scientists, led by cell biologist Victor Faundez, recently analyzed Read more

Cassandra Quave

We are excited that the ASM Microbe meeting will be at the Georgia World Congress Center from June 7 to June 11. If you are interested in antibiotic resistance, you can learn about how to detect it, how to (possibly) defeat it and how the bacteria fight back.

A host of Emory microbiologists are participating. In some cases, our scientists are presenting their unpublished data for discussion with their colleagues at other universities. Accordingly, we are not going to spill the beans on those results. However, please find below some examples of who’s talking and a bit of explanatory background. ASM Microbe abstracts are available online for posters, but not for some symposiums and plenary talks.

David Weiss lab — Klebsiella

Graduate student Jessie Wozniak is presenting her research on an isolate of Klebsiella that combines alarming properties. She will describe how the bacterial colonies behave (unappetizingly) like stretchy melted cheese in a “string test.”

Dunham, a structural biologist, is giving a plenary talk June 11 on toxin-antitoxin pairs, which play a role in regulating bacterial persistence, a dormant state that facilitates antibiotic resistance. Two pastpapers from her lab.

Phil Rather lab – Acinetobacter baumannii

Rather’s lab recently published a Nature Microbiology paper on A. baumannii’s virulence/opacity switch. This type of bacteria is known for hospital-associated infections and for wound infections in military personnel. Poster talk by graduate student Sarah Anderson June 8. Read more

One of the speakers at Thursday’s Antibiotic Resistance Center symposium, Gerald Wright from McMaster University, made the case for fighting antibiotic resistance by combining known antibiotics withÂ non-antibiotic drugs that are used to treat other conditions, which he called adjuvants.

As an example, he cited this paper, in which his lab showed that loperamide, known commercially as the anti-diarrhealÂ Immodium, can make bacteria sensitive toÂ tetracycline-type antibiotics.

Wright said that other commercial drugs and compounds in pharmaceutical companies’ libraries could have similar synergistic effects when combined with existing antibiotics. Most drug-like compounds aimed at human physiology follow “Lipinski’s rule of five“, but the same rules don’t apply to bacteria, he said. What might be a more rewarding place to look for more anti-bacterial compounds? Natural products from fungi and plants, Wright proposed.

“I made a little fist-pump when he said that,” says Emory ethnobotanist Cassandra Quave, whose laboratory specializing in looking for anti-bacterial activities in medicinal plants.

Indeed, many of the points he made on strategies to overcome antibiotic resistance could apply to Quave’s approach. SheÂ and her colleagues have been investigatingÂ compounds that can disruptÂ biofilms, thusÂ enhancingÂ antibiotic activity. More at eScienceCommonsÂ and at her lab’s site.